"2014-09-02+02:00"^^ . . "P(GPP102/12/P613)" . . . . . "Mach, Pavel" . . . "6"^^ . . . "handover; prediction; channel quality; small cells"@en . "Washington D.C." . "3"^^ . "21230" . "40982" . "Calvanese Strinati, E." . "Be\u010Dv\u00E1\u0159, Zden\u011Bk" . "2166-9589" . "RIV/68407700:21230/14:00223318!RIV15-GA0-21230___" . . . "2"^^ . . "Q-Learning-based Prediction of Channel Quality after Handover in Mobile Networks"@en . "Q-Learning-based Prediction of Channel Quality after Handover in Mobile Networks" . . "To avoid call drops after handover due to unavailability of radio resources at a target handover cell, call admission control procedure reserves a specific amount of resources for users performing handover to this cell. If a high amount of resources is reserved, the available capacity for users served by the cell is lowered. Contrary, if a low amount of resources is booked for users entering the new cell, handover cannot be performed and user's connection is dropped. To optimize the amount of reserved resources, we propose an algorithm for prediction of channel quality between the user and the target cell after completing handover to the target cell. The algorithm is based on the knowledge of handover hysteresis and on decomposition of overall interference caused by other cells in the network. The prediction accuracy is tuned by correction parameter, which is dynamically set based on Q-learning approach. As the results show, the proposed algorithm with learning improves the efficiency of channel quality prediction up to twice comparing to conventional solution." . "IEEE 25th Annual International Symposium on Personal, Indoor and Mobile Radio Communications" . . . "RIV/68407700:21230/14:00223318" . "Q-Learning-based Prediction of Channel Quality after Handover in Mobile Networks" . "Q-Learning-based Prediction of Channel Quality after Handover in Mobile Networks"@en . "Piscataway" . . . "IEEE Conference Publications" . "[D23880EAA6C4]" . "To avoid call drops after handover due to unavailability of radio resources at a target handover cell, call admission control procedure reserves a specific amount of resources for users performing handover to this cell. If a high amount of resources is reserved, the available capacity for users served by the cell is lowered. Contrary, if a low amount of resources is booked for users entering the new cell, handover cannot be performed and user's connection is dropped. To optimize the amount of reserved resources, we propose an algorithm for prediction of channel quality between the user and the target cell after completing handover to the target cell. The algorithm is based on the knowledge of handover hysteresis and on decomposition of overall interference caused by other cells in the network. The prediction accuracy is tuned by correction parameter, which is dynamically set based on Q-learning approach. As the results show, the proposed algorithm with learning improves the efficiency of channel quality prediction up to twice comparing to conventional solution."@en . . "978-1-4799-4912-0" .